DE10020982C2 - Vehicle speed control device for a motor vehicle - Google Patents

Description

The present invention relates to a vehicle speed Control device for automatically controlling a vehicle speed to a vehicle in front, which is in front the vehicle travels at a target inter-vehicle distance consequences.

The Japanese (unexamined) published patent application No. Heisei 8-169252, published July 2, 1996 a previously proposed vehicle speed Control device, exemplified.

With the previously proposed vehicle speed A negative driving force is caused by a control device automatic braking system designed to keep a driving speed essentially adjust to the target value.

If such a type of the driving speed described above control device on a preceding vehicle Driving control system is applied, which is a follow-up driving tax tion so that the vehicle is driving ahead stuff that drives in front of the vehicle follows, with an inter Vehicle distance to the vehicle in front is constant a steering behavior regarding the Interfahr distance between tools can be applied.

However, when using the previously proposed driving it can speed control device on the following driving control system stem may be required to brake the vehicle continuously over a long period of time to run the Interfahrzeu there was a constant hold even when the vehicle drives over a long period on a sloping slope.  

DE 198 12 316 A1 describes a driving speed Control device known. With this one determines. Radarcom the distance and relative speed of a ahead vehicle. Become adaptive driving in a computer therefrom control signals for a first control device which the throttle valve of the drive motor acts, as well as for a second control device, which acts on the vehicle brake, generated to the vehicle in front in a particular Distance to follow.

It is therefore an object of the present invention to To provide vehicle speed control device, which egg ne continuous actuation of a vehicle brake via a considerably long period of time in operation of the vehicle ahead Can prevent following drive control.

According to the invention the task is characterized by the features of the solved claim 1, the subclaims show further advantage stick embodiments of the invention.

The task described above can be accomplished by providing a driving speed control device for a motor vehicle ge be solved, which includes: a first computer for calculating a target driving speed to an actual in the vehicle distance from the vehicle to another vehicle, driving in front of the vehicle, essentially to a target To adjust inter-vehicle distance, a second computer for Calculation of a target vehicle driving force to an actual driving speed essentially the target Adjust driving speed, a first control device device, which is an engine output of a vehicle engine controls to an actual engine output to match the target vehicle driving force, a second Control device responsive to a negative target driving force responds to a manipulated variable of a mechanical brake  Control vehicle braking system to a vehicle braking force in the Essentially related to the negative target vehicle driving force men with an actuation of the first control device same, a braking force integrator to the manipulated variable of mechanical brake of the vehicle brake system over time integrating time, and a follow-up drive release Control device for follow-up driving control of the vehicle, which the other vehicle at the target inter-vehicle distance followed by the first and second control devices sen when an integration value of the manipulated variable of a mechani brake over a period of time by the brake force integration tor exceeds a preset reference value.

Fig. 1A is a schematic representation of the structure of a vehicle speed control device of a first preferred embodiment of the present invention.

Fig. 1B is a schematic block diagram of the Fahrgeschwin digkeits control apparatus of the first preferred execution example.

Fig. 2A is a functional block diagram of a follow-up traveling control apparatus shown in Fig. 1A and 1B.

Fig. 2B is a block diagram of the driving speed control apparatus of a second preferred embodiment according to the Invention.

Fig. 3 is a functional block diagram of a driving speed control device of a second preferred embodiment.

Fig. 4 is a functional block diagram of the following driving control device shown in Figs. 1A and 1B for explaining a calculation method of a target throttle valve opening angle Thr * and a target brake fluid pressure Pbrk * of the first preferred embodiment.

Fig. 5 is an explanatory diagram for explaining a method for determining a reference value Kbp bezüg Lich a target command value of a mechanical brake.

Fig. 6 is an explanatory view for explaining a driving Ver for determining an occurrence of brake fade phenomenon during execution of a Fol danger control in the follow-up running control device of the first preferred embodiment, illustrated in Fig. 1A and 1B.

FIG. 7 is a flowchart for explaining a prevention procedure regarding the occurrence of the braking vibration phenomenon, which is executed in the following driving control device shown in FIGS . 1A and 1B.

Furthermore, reference is made to the drawing in order to To facilitate understanding of the present invention.

Fig. 1A shows an explanatory view of a motor vehicle, to which a vehicle speed control device of a first preferred embodiment according to the invention is applicable.

In Fig. 1A, an inter-vehicle distance sensor 1 is a radar type sensor head so that a laser beam scans over a given scanning angle in a width direction (left-and-right direction in a forward detection range to the vehicle), and the reflected rays are from an object (Objects) received, which is (are) generally present in the forward detection area, which is defined by the scanning angle for detecting the object (the objects), for example, of a preceding vehicle.

It should be noted that an electromagnetic wave or an ultrasound wave instead of the laser beam as a medi order can be used.

The inter-vehicle distance sensor 1 is exemplified by US Patent No. 5,710,565, issued January 14, 1998.

A vehicle speed sensor 2 is attached to an output shaft of an automatic transmission 4 to output a pulse train signal whose period is in accordance with a rotational speed of the output shaft of the automatic transmission 4 of the vehicle.

It should be noted that the automatic transmission 4 may be a continuously variable transmission (a so-called CVT).

A throttle valve section operating device 3 (formed by, for example, a DC motor) operates a throttle valve of a motor belonging to the automatic transmission 4 so that it opens or closes in response to a throttle valve opening angle command so that an intake air amount in an air intake passage of the engine which is supplied to the engine is changed to set an engine output torque.

The automatic transmission 4 changes a gear ratio (gear ratio in the case of the CVT) in accordance with the vehicle speed Vs and the engine output torque described above.

A vehicle brake system 6 is constructed of an actuator of a vacuum boost type and is used to build up a braking force applied to the vehicle shown in FIG. 1A.

A following driving control device 5 comprises a microcomputer and its peripheral circuit arrangement, as shown in FIG. 1B.

The microcomputer of the control device 5 generally includes a CPU (central processing unit), a RAM (read-write memory), a ROM (read-only memory), an input port, an output port and a common bus, as shown in FIG. 1B ,

The following driving control device 5 calculates a target driving speed based on a detected value of the inter-vehicle distance between the vehicle and a vehicle in front (another vehicle that is traveling in the same lane in front of the vehicle) and controls an operation of the throttle valve position operating device 3 , the gear ratio of the automatic transmission 4 and a brake fluid pressure of the brake system 6 .

The following driving control device 5 forms control blocks 11 , 21 , 50 and 51 shown in FIG. 2A on a software basis. A details of the operation of the following driving control device 5 will be described below.

Fig. 2 shows a functional block diagram of the following driving control device 5 in the first preferred embodiment of the invention.

In Fig. 2, a measurement distance signal processing block 11 measures a time period from when the laser beam is scanned for scanning over the forward detection range by the inter-vehicle distance sensor 1 to when the reflected laser beam follows it by the inter-vehicle distance ( Space distance) from the vehicle in which the device shown in FIG. 1A is built to calculate the vehicle in front.

It should be noted that when a plurality of such preceding vehicles as described above are detected by the inter-vehicle distance sensor 1 , one of the preceding vehicles to be followed is specified and its inter-vehicle distance, which is the preceding vehicle to be specified is calculated.

Since such a method for selecting the specified egg NEN preceding vehicle is known, the exact loading spelling thereof omitted here.

It should be noted that the selection process by the U.S. Patent No. 5,710,565, issued January 20, 1998 to is shown playfully.

A vehicle speed measurement block 21 measures a period of the vehicle speed pulses from the vehicle speed sensor 2 to derive the vehicle speed Vs.

A driving control block 50 for following a preceding vehicle includes a relative speed calculation section 501 , an inter-vehicle distance control section 502, and a target inter-vehicle distance setting section 503 .

The driving control block 50 for following a preceding vehicle calculates a target inter-vehicle distance L * and a target driving speed V * based on the inter-vehicle distance L and the driving speed Vs. The relative speed calculation section 501 calculates a relative speed .DELTA.V to the preceding vehicle based on the actual inter-vehicle distance L, which is detected by the measurement distance signal processing block 11 .

The inter-vehicle distance control section 502 calculates the target inter-vehicle distance V * to substantially adjust the inter-vehicle distance L to the target inter-vehicle distance L *, taking the relative speed ΔV into account.

The target inter-vehicle distance setting section 503 sets the target inter-vehicle distance L * in accordance with the running speed of the preceding vehicle V _T and the running speed Vs, respectively.

The vehicle speed control section 51 includes a driving force calculation section 511 ; a driving force distribution control section 512 ; a throttle control section 513 ; and a brake system control section 514 .

The vehicle speed control section serves to control the vehicle drive force or vehicle braking force and the gear ratio of the automatic transmission 4 to substantially adjust the vehicle speed Vs to the target vehicle speed V *. The driving force calculating section 511 calculates a target driving force For * to make the vehicle speed Vs substantially equal to the target vehicle speed V *.

The driving force distribution control section 512 serves to divide the target driving force For * into the engine driving force (corresponding to a target throttle valve opening angle Thr *) and the braking force (corresponding to a target brake fluid pressure Pbrk *), these target variables each being at the throttle valve Control section 513 and the brake control section 514 are output.

The throttle control section 513 serves to set an opening angle of the throttle actuator 3 in accordance with the target throttle opening angle Thr *. On the other hand, the brake control section 514 serves to adjust the brake fluid pressure of the vehicle brake system 6 in accordance with the target brake fluid pressure Pbrk *.

An inter-vehicle distance control system and a vehicle speed control system in the vehicle speed speed control device of the first preferred embodiment game described.

Inter-vehicle distance control system

This control system is using a state return Coupling (control device) designed as this control system is an one-input-two-output system in which two Target values of the inter-vehicle distance and the relative speed through a single input variable (that is, the target Driving speed) can be controlled.

State variables of this control system x ₁ and x ₂ are defined in the following equations (1) and (2):

x ₁ = V _T - V _S (1)

x ₂ = L * - L (2)

In equations (1) and (2), V _T denotes the driving speed of the preceding vehicle, Vs denotes the driving speed of the vehicle to be controlled, L * denotes the target inter-vehicle distance, and L denotes the actual inter-vehicle distance.

In addition, a control input (an output of the control device) is ΔV * and is defined in the following equation (3).

ΔV * = V _T - V * (3)

The inter-vehicle distance L is defined as follows:

L = ∫ (V _T - Vs) dt + L ₀ (4)

In the equation (4), L ₀ denotes an initial value of the inter-vehicle distance.

In the case of a vehicle speed servo system, the actual vehicle speed Vs can be approximated to the target vehicle speed V * as follows, for example in the event of a deceleration of the first order:

Vs = 1 / (1 + τvS) V * (5)

In equation (5) τv denotes a time constant of the vehicle speed servo system, and it denotes a difference tial operator (S = d / dt).

It is assumed that the running speed of the preceding vehicle is constant. The following equation (6) can be derived.

₁ = -1 / τv.x ₁ + 1 / τv.ΔV * (6)

It is further assumed that the target inter-vehicle distance L * is constant. The following equation (7) can be derived from equations (3) and (4).

₂ = - (V _T - Vs) = -x ₁ (7)

Therefore, the equation of state of this system can be Equation (8) shown in Table 1 can be described.

If the control input variable µ (ΔV *) is given as

µ = FX F = [fv fd] (9),

the state equation of the system in which a state feedback loop is executed can be represented as follows:

 = (A + BF) X (10).

In addition, the equation of state can also be modified as in one in Ta equation (11) shown in belle 1 can be given.

A characteristic equation of the system can be represented as follows:

| sI - A '| = s ² + (1 - fv) / τvS + fd / τv = 0 (12)

Control gains fd (for the inter-vehicle distance Control system) and fv (for the vehicle speed Tax system) are determined in such a way that characteristics, which the inter-vehicle distance L towards the target Inter vehicle distance L * converge and the Relativge speed ΔV converge to zero, desired Characteristics result.  

This means,

S ² + (1 - fv) /τv.S + fd / τv = S ² + 2ξωnS + ωn ² = 0 (13),

where ξ denotes a damping factor, ωn denotes a specific angular frequency.

fv = 1 - 2ξωn.τv (14),

and

fd = ωn ² .τv (15).

Therefore, the target vehicle speed V * for performing the inter-vehicle distance control can be derived from the equations (3) and (9) as follows.

V * = V _T - ΔV *

= (1 - fv) ΔV + fd (L * - L) + Vs (16),

where V _T = Vs - ΔV.

Vehicle speed control system

For example, the vehicle speed control system is on built from a robust compensator, which is a kind of Disturbance estimator, and a model matching Compensator, which the response characteristic of an entire System essentially to a response characteristic of a Reference model aligned to provide a tax system, wel against external disturbances, such as a change in Road slope, is robust. The driving speed Control system is using a robust model adaptation technology designed.

Fig. 3 is a control block diagram of the driving speed is a control system in the vehicular velocity control apparatus of the first preferred embodiment.

The robust compensator is used to estimate and correct the Disturbance, such as a modeling error of an ob to be controlled project (that is, the vehicle to be controlled) and driving resistance.  Therefore, the robust compensator can control stem form, which the actual vehicle characteristics in We approximates to a linear model Gv (s).

In Fig. 3, H (s) denotes a transfer function of a robust filter for determining a disturbance variable characteristic elimination performance.

The robust filter can be defined as follows:

H (s) = 1 / (1 + τcS) (17),

where τc denotes a time constant.

The model matching capacitor is used to determine a response characteristic with regard to a system input variable and a system output variable by means of a reference model R ₂ (S) of a feedforward section and to determine the interference variable limitation power and the stability by means of a. Reference model R ₁ (S) of a feedback section.

For example, the model adaptation compensator is made up of a robust filter, which can be expressed as in the following equation (18).

R ₁ (S) = 1 / (1 + T ₁ S) (18), and

R ₂ (S) = 1 / (1 + T ₂ S) (19)

The linear vehicle approximation model Gv (S) is an integration characteristic as given in the following equation (20).

Gv (S) = 1 / MS (20),

where M denotes a vehicle weight.  

From the equations (1) to (20) described above, a target driving force For * can be derived as follows:
This means,

For (S) = R ₁ (S) / {Gv (S) (1 - R ₁ (S)} {R ₂ (S) / R ₁ (S) V * - V} = M / T ₁ {(1 + T ₁ S)} / {1 + T ₂ S} V * - V} (21).

Furthermore, an equation (22) shown in Table 1 can be used be directed.

It should be noted that a negative target Driving force For * means the target braking force, and if that Target braking force is mentioned throughout the description, so the target braking force is included within the meaning of the expression.

Fig. 4 shows a method for calculating a target throttle opening angle Thr * and a target brake fluid pressure Pbrk *.

In FIG. 4, the following driving control device converts the target motor torque Ter * from the target driving force For * from the target driving force For * into the following equation.

Ter * = Rt / (Gm Gf) For * (23)

In equation (23), Rt denotes an effective radius of a tire of a representative tire wheel of the vehicle, Gm denotes a gear ratio of the automatic transmission 4 , and Gf denotes an end gear ratio.

It should be noted that a negative target engine torque Ter * is a braking torque and is obtained by means of an engine braking torque during a full closing operation of the throttle valve in the case of the first preferred embodiment. However, in the event that the braking torque is not sufficient only by the engine braking torque, a mechanical brake by the vehicle braking system 6 is used together with the engine braking torque.

The target throttle opening angle Thr * corresponds to that Target engine torque Ter * and the engine speed Ne becomes below Using a table search technique for a non-linear Compensation map regarding the opening angle of the Dros selflap based on a preset mo torque and a preset engine speed Ne [Rpm] derived.

On the other hand, the target brake fluid pressure Pbrk * is calculated as follows when the target throttle opening angle Thr indicates zero as the calculation result. That is, the engine torque Te0 during the fully closed state of the throttle valve with respect to the preset engine speed is derived from the engine torque map shown in FIG. 4.

The target brake fluid pressure Pbrk * is calculated by Subtract the engine torque Te0 during full closing operating the throttle valve from the target engine torque Ter *.

This means,

Pbrk * = -GmGf / 4 (2 Ab Pb µb) (Ter * - TeO) (24).

In equation (24) Ab denotes a wheel cylinder area, Pb denotes an effective radius of a brake disc, and µb denotes a coefficient of friction of a brake pad.

The following is a method of preventing an appearance tens of a braking fading phenomenon described by  the vehicle speed control device before the first drafted embodiment is executed.

In the above-described vehicle speed control device, the target negative driving force is calculated to decelerate the controlled vehicle in any case in which the inter-vehicle distance to the preceding vehicle is shortened and in which the vehicle is on a down slope (downhill ) moves. Here, when the deceleration force is no longer sufficient simply by the engine braking when the engine throttle valve is fully closed, the mechanical brake is used by the vehicle braking system 6 together with the engine braking.

Especially when the vehicle is behaving on one of these long and abrupt falling slope a large negative driving force required to the Inter vehicle distance to keep constant, one due to a Acceleration occurring road slope to sea level is reduced to obtain the negative acceleration.

As a result, there is a possibility of applying the mechanical brake to the road wheels for a long period of time. If the mechanical brake is applied to the road wheels for a long period of time, the vehicle brake system 6 heats up, so that a braking distance increases (a so-called braking fading phenomenon occurs). Therefore, the braking force is reduced, so that the inter-vehicle distance to the preceding vehicle can no longer be maintained, and the mentioned braking performance is impaired during normal driving (no execution of control to follow a preceding vehicle).

In the first preferred embodiment, a state of continuous application of a mechanical brake is detected or estimated by the brake system 6 . If there is a possibility that the fading will occur, the following driving control is released to prevent the fading from occurring.

Such a state of application of a mechanical brake as an opportunity for the braking faders to appear soon Apparition is based on the following procedure ner continuous time determined, for example the target brake fluid pressure Pbrk * is output.

First, a time in which a temperature of a brake pad reaches about 1/2 the temperature of the temperature at which the brake fading occurs is defined and is a reference time. A representative value of the reference time is derived by experimentally measuring a temperature rise at a constant brake fluid pressure and applying the constant brake fluid pressure to the brake system 6 to apply the braking force to the road wheels.

For example, as shown in Fig. 5, since a fading temperature of the brake pad made of a generally available material is between 700 ° C and 800 ° C, the time for the brake pad temperature to rise to half from 700 ° C to 800 ° C (the means, 400 ° C) measured, and the representative value with respect to the measured time is assumed as the reference time t0.

In addition, the brake fluid pressure P used during the above measurement for the reference time t0 a brake fluid pressure P0, for example, the vehicle deceleration of 0.3 G to 0.5 G, which are commonly used to generate gene.  

Next, the brake fluid pressure (P = P0), which is used for the measurement of the reference time t0, for the Be train time t0 integrated to a reference value Kbp with respect to ner continuous brake manipulated variable to determine.

Heat generated at the brake pad is proportional to that Braking force and a braking period, and the braking force is proportional to the brake fluid pressure. If a high one Fluid pressure is applied continuously, so is the Temperature rise of the brake pad quickly. If a lower one Fluid pressure is applied continuously, so the Brake pad temperature rise in accordance with the Braking force can be predicted.

In order to actually determine the occurrence of the braking fading during the follow-up control, the follow-up control device 5 integrates the target brake fluid pressure Pbrk * during the follow-up control over time, so that the integration value is compared with the reference value Kbp described above.

When the integration value bP of the target brake fluid pressure Pbrk * becomes larger than the reference value Kbp, the following risk control device 5 determines that there is a high possibility that the braking fading phenomenon will occur soon, and releases the following driving control.

It should be noted that the time integration of the target Brake fluid pressure Pbrk * is only executed if the target brake fluid pressure Pbrk * is not zero. Furthermore, the integration value bP is reset when the Target brake fluid pressure Pbrk * at time t00 to t01 and t10 to t11 do not exceed zero, the target Brake fluid pressure Pbrk * is measured over time for each time tinterval t00 to t01 and t10 to t11 integrated. If the  Integration value bP exceeds the reference value Kbp, then the following driving control solved.

In an example shown in FIG. 6, the following driving control is released at a point in time t11 since the time integration value bP with respect to the target brake fluid pressure exceeds the reference value KbP. Note that at time t01, the target brake fluid pressure Pbrk * indicates zero. If Pbrk * = 0, the integration value bP is reset once. Subsequently, the time integration of the target brake fluid pressure Pbrk * is resumed from the time t10 at which the time integration of the target brake fluid pressure Pbrk * is resumed.

After the time integration value of the brake fluid pressure Pbrk * is greater than the reference value Kbp and the following drive control is solved, it being determined that a large There is a probability that the fading phenomenon will occur occurs, the engine is stopped at least once, and the how it will not be possible to start the follow-up drive control for so long light until the engine is restarted.

Fig. 7 shows a flowchart which is carried out in the first embodiment of the vehicle speed control device and explains the procedure for preventing occurrence of the fading phenomenon.

The following driving control device 5 repeatedly executes a routine shown in FIG. 7 as a timer interrupt routine.

That is, in a step S1, the CPU of the following driving control device 5 determines whether the target brake fluid pressure Pbrk * exceeds zero. If Pbrk * <0, the routine proceeds to step S2. In step S2, the following driving control device 5 integrates the target brake fluid pressure Pbrk * over time. It should be noted that the target brake fluid pressure Pbrk * is calculated in the manner described above using another program.

In a step S3, the following driving control device 5 confirms the time-integrated value bP for the target brake fluid temperature Pbrk * with the reference value KbP.

If the integration value bP exceeds the reference value KbP, so the routine proceeds to a step S4, in which the Follower control is solved. More specifically, solving the Sequence control the output of the target Throttle valve opening angle Thr *, and the target Brake fluid pressure Pbrk * is set to zero.

In addition, in the next step S5, the following driving control device 5 confirms whether an ignition key switch (not shown) is operated to stop the engine 3 .

If the engine 3 is stopped, the routine proceeds to step S6. In step S6, the following driving control device 5 confirms whether the engine 3 is restarted, and the routine proceeds to step S7. In step S7, the following driving control device 5 enables the following driving to be restored.

On the other hand, when the time integration value bP of the target brake fluid pressure Pbrk * is equal to or less than the reference value KbP, the routine proceeds to step S8. In step S8, the following driving control device 5 confirms whether the target brake fluid pressure Pbrk * indicates zero. If Pbrk * = 0 in step S8, the routine proceeds to step S9 in which the time integration value bP with respect to the target brake fluid pressure is reset to zero, and the routine returns to step S1 to do the above Repeat procedure. If Pbrk * ≠ 0 in step S8, the routine returns to step S2 to continue the time integration with the target brake fluid pressure Pbrk *.

As described above, the reference value KbP with respect to the continuous brake manipulated variable is determined on the basis of the temperature rise period of the brake pad (although the brake pad is installed for each road wheel, this brake pad is a representative brake pad for the respective road wheels) using the constant brake fluid pressure, whereby the reference value is a measure for determining the occurrence of the braking fading phenomenon. Further, the control device 5 determines when the time integration value bP of the target brake fluid pressure Pbrk * during the following driving control exceeds the reference value KbP that there is a high likelihood of the occurrence of the braking fading and releases the following driving control.

Therefore, in a case where the following driving control is carried out to follow the preceding vehicle while the simultaneous operations of the engine braking and the vehicle braking by the vehicle braking system 6 are preceded, the vehicle speed control device can prevent the braking fading phenomenon from occurring while applying the mechanical brake is continuously applied over the long period of time.

It should be noted that the reference value KbP regarding the continuous brake control variable in accordance with the road slope can be corrected.

For example, when the vehicle drops on the abrupt low slope with a steep road slope, one  Frequency of applying the mechanical brake even then increased when the vehicle is running in the normal driving mode which a following driving control is not carried out. Therefore it is necessary to have sufficient braking scope to maintain performance even after releasing the follow-up drive control. To meet this requirement, the reference value KbP with regard to the continuous brake manipulated variable, which too before was fixed, corrected to be smaller is so that the following driving control at an earlier time point is solved. The road inclination can be done directly using ei of an inclinometer or from that on a front available point of the vehicle through a vehicle navigation system stem are recorded.

In addition, based on the first embodiment described above example the determination of the braking fading on the Time integration of the target brake fluid pressure Pbrk *, if the target brake fluid pressure Pbrk * is not zero. however can take into account the cooling of the brake pad If the integration value does not occur even then is reset when the target brake fluid pressure Pbrk * temporarily indicates zero, and determining the occurrence the fading phenomenon can be based on an accumulated value of the Time integration value of target brake fluid pressure Pbrk * based within a predetermined period of time.

Further, Fig. 2B shows a system configuration of a second before ferred embodiment of the driving speed control device.

As shown in FIG. 2B, the following drive controller 5 is separated from an engine throttle control device 513 'and a brake control device 514 '. In the second exemplary embodiment, the actual brake fluid pressure Pbrk is detected by means of each brake fluid pressure sensor 5 f, which is arranged in a corresponding working fluid pressure passage between a master cylinder M / C 6B and a large number of wheel cylinders W / C 6C of the vehicle brake system 6 , and the detected brake fluid pressure Pbrk (an average of each brake fluid pressure can be used) is integrated over time in the same manner as the brake fluid pressure Pbrk * as described in the first embodiment.

The following driving control device 5 ( 21 , 50 , 511 , 512 ) relates to the detected brake fluid pressure Pbrk for calculating the time integration thereof. Note that a reference numeral 52 'in FIG. 2B corresponds to the vehicle 52 to be controlled shown in FIG. 2A, except that the brake fluid pressure sensor (the brake fluid pressure sensors) 5 f is (are) arranged in the brake fluid pressure channels, a reference symbol 3 a denotes a throttle valve actuating device, which is formed for example by a DC motor, 3C denotes the engine throttle flap, 3B denotes an opening angle sensor (example, a potentiometer) for detecting the opening angle of the throttle valve 3 C, 6 a denotes a Bremsenbetätigungsvor direction for actuating the Master cylinder in response to a SOL.CB signal (solenoid current signal) from brake control device 514 '. The other structures in the second embodiment are generally the same as those in the first embodiment.

In the second embodiment, the detected value of Brake fluid pressure Pbrk integrated over the period, and the time-integrated value (integration value) of the detected Brake fluid pressure is compared with the reference value KbP chen used in the first embodiment becomes.  

Therefore, the target brake fluid pressure Pbrk *, which is described in steps S1, S2 and S8 shown in FIG. 7, is replaced by Pbrk in the second embodiment.

Although the follow-up running control device 7 performs the fading prevention procedure presented in Fig. 7 Darge, the brake may control device execute 'the Schwundver shown in Fig. 7514 hinderungsprozedur. In this alternative case, the brake control device 514 'issues a release request command to the following drive control device (also referred to as an ACC control device) 21 , 50 , 511 and 512 to output a target brake fluid pressure Pbrk * of zero.

It should be noted that the above-described reference value KbP is measured experimentally, such as 15 (MPa) × 3 (seconds) × 10 (braking frequency) = 450 (MPa), and the reference time t0 shown in FIG. 5 is, for example 150 seconds since a maximum brake fluid pressure used in the following driving control device (ACC control device) shown in FIG. 2B is 3 MPa.

It should also be noted that the accumulated value of the target brake fluid pressure Pbrk * is compared with the same reference value KbP with respect to the continuous brake manipulated variable used in the flowchart shown in FIG. 5, and the predetermined temperature is about 400 ° C.

In summary, the present invention relates to driving speed control device for a motor vehicle, at which is a first computer for calculating a target Driving speed is provided to an actual In the vehicle distance from the vehicle to another vehicle,  driving in front of the vehicle, essentially to a target Adjust inter-vehicle distance, a second computer is available Calculation of a target vehicle driving force is provided to ei ne actual driving speed essentially the target To adjust driving speed, a first control device is operated such that it is an engine output a vehicle engine controls to an actual engine initial size essentially the target vehicle drive size at the same time, a second control device responds to a ne negative target driving force to a manipulated variable of a mecha African brake of a vehicle brake system to control a Vehicle braking force essentially to the negative target Vehicle driving force together with actuation of the first Adjust control device is a braking force integrator provided to control the manipulated variable of a mechanical brake Integrate vehicle braking system over a period of time, and a follow-up release control device is provided to a Follow-up driving control of the vehicle which is the other vehicle at the target inter-vehicle distance by the first and the second control device follows to solve when an integrati value of the manipulated variable of a mechanical brake via a Time set by the brake force integrator exceeds the reference value.  

TABLE 1

Claims (5)

1. A vehicle speed control device for a motor vehicle, comprising:
a first calculator for calculating a target vehicle speed to substantially match an actual inter-vehicle distance from the vehicle to another vehicle traveling in front of the vehicle with a target inter-vehicle distance;
a second calculator for calculating a target vehicle driving force to substantially match an actual driving speed with the target driving speed;
a first controller that controls an engine output of a vehicle engine to substantially match the actual engine output to the target vehicle driving force;
a second control device which is responsive to a negative target drive force in order to control a manipulated variable of a mechanical brake of a vehicle brake system ( 6 ) in order to substantially adapt a vehicle brake force to the negative target vehicle drive force together with an actuation of the first control device ;
a braking force integrator in order to integrate the manipulated variable of the mechanical brake of the vehicle braking system ( 6 ) over a period of time; and
a follow-up release control device to release a follow-up drive control of the vehicle following the other vehicle at the target inter-vehicle distance by the first and second control devices when an integration value of the manipulated variable of a mechanical brake over a period of time by the brake force integrator exceeds a preset reference value. 2. Vehicle speed control device for a motor vehicle according to claim 1, wherein the brake force integrator comprises a target brake fluid pressure integrator for integrating a target brake fluid pressure for the vehicle brake system ( 6 ) over the period of time, wherein the target brake fluid pressure approximately a part of corresponds to the negative target vehicle driving force to be exerted by the vehicle braking system ( 6 ). 3. Vehicle speed control device for a motor vehicle according to claim 1, further comprising a brake fluid pressure detector for detecting a brake fluid pressure of the vehicle brake system ( 6 ), wherein the brake force integrator integrates a detected value of the brake fluid pressure detected by the brake fluid detector over the period of time, the Brake fluid pressure corresponds to the manipulated variable of a mechanical brake. 4. vehicular velocity control apparatus for an automotive vehicle according to claim 2, wherein the preset reference value, an integration value of the brake fluid pressure for a temperature of a brake pad of the vehicle brake system (6) of a predetermined value upon actuation of the vehicle brake system (6) with a predetermined brake is fluid pressure is reached. 5. Driving speed control device for a motor vehicle Stuff according to claim 1, wherein the follow-drive release Control device a restoration of the following danger control, which was released, blocked until the drive Witness motor is restarted after the motor stops has been.